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2. Tenth Annual Meeting of the European Association for the Study of Diabetes: Jerusalem, Israel, September 11–13, 1974

Author

Alberti, K. G. M. M., Iversen, J., Christensen, N. J., Andersson, A., Jarrousse, Claire, Andersson, Arne, Hellerström, Claes, Andreani, D., Tamburrano, G., Tamburrano, S., Gambardella, S., Ardill, Joy, Montgomery, D. A. D., Hadden, D. R., Assan, R., Attali, J. R., Selmi, A., Bourdillat, N., Soufflet, E., Girard, J. R., Bajaj, J. S., Chinna, G. S., Garg, S. K., Singh, Baldev, Balasse, E. O., Neef, M. A., Beischer, W., Melani, F., Keller, L., Hinz, M., Kroder, A., Maier, V., Pfeiffer, E. F., Bendayan, M., Sandborn, E., Rasio, E., Bensoussan, D., Levy-Toledano, S., Passa, P., Caen, J., Berger, M., Goodman, M. N., Hagg, S. A., Ruderman, N. B., Beyer, J., Cordes, U., Travniczek, H., Heider, W., Schöffling, K., Happ, J., Grimm, H., Pünchera, W., Althoff, P. H., Fröhlich, A., Bianco, A. R., Schwartz, R. H., Handwerger, B. S., Blackshear, P. J., Holloway, P. A. H., Williamson, D. H., Boquist, L., Hellman, Bo, Lernmark, Åke, Täljedabl, Inge-Bert, Bottermann, P., Schweigart, U., Zilker, Th., Hansen, W., Brachet, E., Rogister, C., Broer, Y., Freychet, P., Rosselin, G., Brunengraber, H., Vertongen, F., Boutry, M., Camu, F., Christacopoulos, P., Karamanos, B., Papadimitriou, P., Kardatos, Ch., Christensen, Niels Juel, Neubauer, Bent, Christophe, Jean, Winand, Jacques, Dehaye, Jean, Cuendet, G. S., Loten, E. G., Jeanrenaud, B., Davis, E., Yodaiken, Ralph E., Yanko, L., Herman, J. B., Garcia, S. Duran, Jarrousse, C., Ditzel, J., Daugaard, Niels Peters, Andersen, Haakon, Egeberg, J., Nerup, J., Andersen, O. O., Kromann, H., Bendixen, G., Poulsen, J. E., Eschwege, E., Falkmer, S., Emdin, S. O., Havu, N., Biuw, L. Winbladh, Sundby, F., Cutfield, J. F., Cutfield, S. M., Dodson, G. G., Peterson, J. D., Steiner, D. F., Fallucca, F., Menzinger, G., Iavicoli, M., Federspil, G., de Palo, C., Zago, E., Casara, D., Zaccaria, M., Scandellari, C., Felber, J. -P., Magnenat, G., Curchod, B., Pittet, Ph., Lytras, N., Müller-Hess, R., Geser, C. A., Jéquier, E., Flanagan, R. W. J., Buchanan, K. D., Murphy, R. F., Fölling, Ivar, Fromantin, M., Freyria, J., Bressac, F., Geisthövel, W., Niedergerke, U., Morgner, K. D., Willms, B., Mitzkat, H. J., Gey, K. F., Bühler, E., Sommer, P., Gey, K. F., Georgi, H., Sommer, P., Lengsfeld, H., Ghiea, D., Costiner, E., Simionescu, L., Oprescu, M., Grill, V., Cerasi, E., Gundersen, H. J. G., Gutman, A., Adler, J., Bar-Or, D., Gutzeit, A., Cerasi, E., Guy-Grand, B., Bigorie, B., Gylfe, Erik, Idahl, Lars-Åke, Hamosh, Margit, Hamosh, Paul, Hart, Adrian, Cohen, H., Thorp, J. M., Hedeskov, C. J., Capito, K., Forruby, B., Henquin, J. C., Lambert, A. B., Lambert, A. E., Henquin, J. C., Hepp, K. D., Renner, R., Häring, H. U., Mehnert, H., Kemmler, W., Löffler, G., Mehnert, H., Herchuelz, A., Mahy, M., Herrera, Emilip, Garcia-Rafanell, J., Morell, J., Heuclin, Ch., Attali, J. R., Girard, J. R., Assan, R., Hicks, B. H., Taylor, C. I., Vij, S. K., Pek, S., Knopf, R. F., Floyd, Jr., J. C., Fajans, S. S., Hockaday, T. D. R., Hockaday, J. M., Mann, J. I., Turner, R. C., Hockaday, T. D. R., Honour, A. J., Ikeda, Y., Saito, S., Matsuura, Y., Obayashi, N., Morimoto, Y., Sano, T., Abe, M., Jacouot, R., Felix, J. M., Legrele, C., Sutter-Dub, M. -Th., Sutter, B. Ch. J., Kammerer, L., Fehér, J., Lévai, J., Dénes, R., Stützel, M., Balázsi, I., Láng, I., Littmann, L., Karakash, C., Assimacopoulos, F., Katsilambros, N., Papadopoulos, G., Varonos, D., Daikos, G., Keen, H., Jarrett, R. J., Fuller, J. H., Kiesselbach, N. H. K., Puls, W., Keup, U., Kikkawa, Ryuichi, Duvillard, D., Ravazzola, M., Stauffacher, W., Köbberling, J., Kattermann, R., Kobberling, J., Creutzfeldt, W., Kohner, Eva M., Hamilton, A. M., Joplin, G. F., Blach, R. K., Fraser, T. R., Kolb, H. J., Weiss, L., Wieland, O. H., Korn, A., Waldhäusl, W., Bonelli, J., Magometsohnigg, D., Hitzenberger, G., Kramp, Robert C., Kremer, G. J., Atzpodien, W., Schnellbacher, B., Krug, B., Mialhe, P., Gross, R., Landgraf, R., Landgraf-Leurs, M., Klingenburg, M., Melamed, I., Hörl, R., Jun, István Láng, Littmann, László, Stützel, Mária, Balázsi, Imre, Langslow, Derek R., Buchanan, Keith D., Freeman, Barry M., Berezin, Meir, Mincu, I., Dumitrescu, C., Ionescu-Tirgoviste, C., Mihalache, N., Boboia, D., Stanescu, J., Ghise-Beer, E., Georgescu, St., Bruckner, I., Popa, I., Muggeo, M., Tiengo, A., Padovan, D., Molinari, M., Müller, Walter A., and Sharp, Geoffrey W. G.

Published
1974
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7. Atomic Positions in Rhombohedral 2-Zinc Insulin Crystals

Author

BLUNDELL, T. L., CUTFIELD, J. F., CUTFIELD, S. M., DODSON, E. J., DODSON, G. G., HODGKIN, D. C., MERCOLA, D. A., and VIJAYAN, M.

Abstract

Atomic positions in three dimensions have been derived for the two non-identical molecules of insulin in rhombohedral 2-zinc insulin crystals. Interesting correlations appear in their relation to the sequence variations observed so far in natural insulins.

Published
1971
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10. Minor structural consequences of alternative CUG codon usage (Ser for Leu) in Candida albicans exoglucanase.

Author

Cutfield JF, Sullivan PA, and Cutfield SM

Subjects
Amino Acid Substitution, Candida albicans genetics, Crystallography, X-Ray, DNA, Fungal, Fungal Proteins chemistry, Glucan 1,3-beta-Glucosidase, Models, Molecular, Molecular Sequence Data, Protein Conformation, beta-Glucosidase chemistry, Candida albicans enzymology, Codon genetics, Protein Biosynthesis genetics, beta-Glucosidase genetics
Abstract

In some species of Candida the CUG codon is encoded as serine and not leucine. In the case of the exo-beta-1,3-glucanase from the pathogenic fungus C. albicans there are two such translational events, one in the prepro-leader sequence and the other at residue 64. Overexpression of active mature enzyme in a yeast host indicated that these two positions are tolerant to substitution. By comparing the crystal structure of the recombinant protein with that of the native (presented here), it is seen how either serine or leucine can be accommodated at position 64. Examination of the relatively few solved protein structures from C. albicans indicates that other CUG encoded serines are also found at non-essential surface sites. However such codon usage is rare in C. albicans, in contrast to C. rugosa, with direct implications for respective recombinant protein production.

Published
2000
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11. The structure of the exo-beta-(1,3)-glucanase from Candida albicans in native and bound forms: relationship between a pocket and groove in family 5 glycosyl hydrolases.

Author

Cutfield SM, Davies GJ, Murshudov G, Anderson BF, Moody PC, Sullivan PA, and Cutfield JF

Subjects
Amino Acid Sequence, Crystallography, X-Ray, Glucan 1,3-beta-Glucosidase, Glycosylation, Humans, Indolizines metabolism, Models, Molecular, Molecular Sequence Data, Protein Conformation, Protein Structure, Tertiary, Static Electricity, Structure-Activity Relationship, beta-Glucosidase metabolism, Candida albicans enzymology, beta-Glucosidase chemistry
Abstract

A group of fungal exo-beta-(1,3)-glucanases, including that from the human pathogen Candida albicans (Exg), belong to glycosyl hydrolase family 5 that also includes many bacterial cellulases (endo-beta-1, 4-glucanases). Family members, despite wide sequence variations, share a common mechanism and are characterised by possessing eight invariant residues making up the active site. These include two glutamate residues acting as nucleophile and acid/base, respectively. Exg is an abundant secreted enzyme possessing both hydrolase and transferase activity consistent with a role in cell wall glucan metabolism and possibly morphogenesis. The structures of Exg in both free and inhibited forms have been determined to 1.9 A resolution. A distorted (beta/alpha)8 barrel structure accommodates an active site which is located within a deep pocket, formed when extended loop regions close off a cellulase-like groove. Structural analysis of a covalently bound mechanism-based inhibitor (2-fluoroglucosylpyranoside) and of a transition-state analogue (castanospermine) has identified the binding interactions at the -1 glucose binding site. In particular the carboxylate of Glu27 serves a dominant hydrogen-bonding role. Access by a 1,3-glucan chain to the pocket in Exg can be understood in terms of a change in conformation of the terminal glucose residue from chair to twisted boat. The geometry of the pocket is not, however, well suited for cleavage of 1,4-glycosidic linkages. A second glucose site was identified at the entrance to the pocket, sandwiched between two antiparallel phenylalanine side-chains. This aromatic entrance-way must not only direct substrate into the pocket but also may act as a clamp for an acceptor molecule participating in the transfer reaction., (Copyright 1999 Academic Press.)

Published
1999
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12. Structure of secreted aspartic proteinases from Candida. Implications for the design of antifungal agents.

Author

Abad-Zapatero C, Goldman R, Muchmore SW, Hutchins C, Oie T, Stewart K, Cutfield SM, Cutfield JF, Foundling SI, and Ray TL

Subjects
Candida drug effects, Drug Design, Humans, Models, Molecular, Protease Inhibitors chemistry, Substrate Specificity, Antifungal Agents pharmacology, Aspartic Acid Endopeptidases antagonists & inhibitors, Aspartic Acid Endopeptidases chemistry, Candida enzymology, Fungal Proteins
Abstract

Pathogens of the genus Candida can cause life threatening infections in immuno-compromised patients. The three-dimensional structures of two closely related secreted aspartic proteinases from C. albicans complexed with a potent (Ki = 0.17 nM) inhibitor, and an analogous enzyme from C. tropicalis reveal variations on the classical aspartic proteinase theme that dramatically alter the specificity of this class of enzymes. The novel fungal proteases present: i) an 8 residue insertion near the first disulfide (Cys45-Cys50, pepsin numbering) that results in a broad flap extending towards the active site; ii) a seven residue deletion replacing helix hN2 (Ser110-Tyr114), which enlarges the S3 pocket; iii) a short polar connection between the two rigid body domains that alters their relative orientation and provides certain specificity; and i.v.) an ordered 12 residue addition at the carboxy terminus. The same inhibitor (A-70450) binds in an extended conformation in the two variants of C. albicans protease, and presents a branched structure at the P3 position. However, the conformation of the terminal methylpiperazine ring is different in the two crystals structures. The implications of these findings for the design of potent antifungal agents are discussed.

Published
1998
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13. The crystal structure of a major secreted aspartic proteinase from Candida albicans in complexes with two inhibitors.

Author

Cutfield SM, Dodson EJ, Anderson BF, Moody PC, Marshall CJ, Sullivan PA, and Cutfield JF

Subjects
Amino Acid Sequence, Antifungal Agents pharmacology, Aspartic Acid Endopeptidases antagonists & inhibitors, Binding Sites, Crystallography, X-Ray, Drug Design, Enzyme Inhibitors pharmacology, Fungal Proteins antagonists & inhibitors, Isoenzymes antagonists & inhibitors, Macromolecular Substances, Molecular Sequence Data, Pepstatins pharmacology, Piperazines pharmacology, Protein Binding, Sequence Alignment, Sequence Homology, Amino Acid, Antifungal Agents chemistry, Aspartic Acid Endopeptidases chemistry, Candida albicans enzymology, Enzyme Inhibitors chemistry, Fungal Proteins chemistry, Isoenzymes chemistry, Models, Molecular, Pepstatins chemistry, Piperazines chemistry, Protein Conformation
Abstract

Background: Infections caused by Candida albicans, a common fungal pathogen of humans, are increasing in incidence, necessitating development of new therapeutic drugs. Secreted aspartic proteinase (SAP) activity is considered an important virulence factor in these infections and might offer a suitable target for drug design. Amongst the various SAP isozymes, the SAP2 gene product is the major form expressed in a number of C. albicans strains., Results: The three-dimensional structures of SAP2 complexed with the tight-binding inhibitor A70450 (a synthetic hexapeptide analogue) and with the general aspartic proteinase inhibitor pepstatin A (a microbial natural product) have been determined to 2.1 A and 3.0 A resolution, respectively. Although the protein structure retains the main features of a typical aspartic proteinase, it also shows some significant differences, due mainly to several sequence insertions and deletions (as revealed by homology modelling), that alter the shape of the binding cleft. There is also considerable variation in the C-terminal structural domain., Conclusions: The differences in side chains, and in the conformations adopted by the two inhibitors, particularly at their P4, P3 and P'2 positions (using standard notation for protease-inhibitor residues), allows the A70450 structure to complement, more accurately, that of the substrate-binding site of SAP2. Some differences in the binding clefts of other SAP isoenzymes may be deduced from the SAP2 structure.

Published
1995
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14. A second glucagon in the pancreatic islets of the daddy sculpin Cottus scorpius.

Author

Cutfield SM and Cutfield JF

Subjects
Amino Acid Sequence, Animals, Chromatography, Gel, Chromatography, High Pressure Liquid, Molecular Sequence Data, Phylogeny, Species Specificity, Fishes physiology, Glucagon metabolism, Islets of Langerhans metabolism
Abstract

The peptide hormone glucagon has been isolated from the islet tissue (Brockmann bodies) of the teleost Cottus scorpius (daddy sculpin) and sequenced. The sequence is HSEGTSNDYSKYLEDRKAQDFVQWLMNN differing at four positions from the glucagon found earlier in the same species by Conlon and coworkers (1987b, Eur. J. Biochem, 164, 117-122). Thus sculpin, in common with anglerfish, possesses two distinct glucagons. Comparative sequence data are presented as a phylogenetic tree.

Published
1993
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17. The amino-acid sequences of sculpin islet somatostatin-28 and peptide YY.

Author

Cutfield SM, Carne A, and Cutfield JF

Subjects
Amino Acid Sequence, Animals, Peptide YY, Somatostatin-28, Species Specificity, Fishes metabolism, Islets of Langerhans analysis, Peptides isolation & purification, Somatostatin isolation & purification
Abstract

Two pancreatic peptides, somatostatin-28 and peptide YY, have been isolated from the Brockmann bodies of the teleost fish Cottus scorpius (daddy sculpin). Following purification by reverse-phase HPLC, each peptide was sequenced completely through to the carboxyl-terminus by gas-phase Edman degradation. Somatostatin-28 was the major form of somatostatin detected and is similar to the gene II product from anglerfish. Peptide YY (36 amino acids) more closely resembles porcine neuropeptide YY and intestinal peptide YY than it does the pancreatic polypeptides.

Published
1987
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18. The structure of 2Zn pig insulin crystals at 1.5 A resolution.

Author

Baker EN, Blundell TL, Cutfield JF, Cutfield SM, Dodson EJ, Dodson GG, Hodgkin DM, Hubbard RE, Isaacs NW, and Reynolds CD

Subjects
Animals, Disulfides, Hydrogen Bonding, Macromolecular Substances, Models, Molecular, Protein Conformation, Swine, X-Ray Diffraction, Insulin, Zinc
Abstract

The paper describes the arrangement of the atoms within rhombohedral crystals of 2Zn pig insulin as seen in electron density maps calculated from X-ray data extending to 1.5 A (1 A = 10(-10) m = 10(-1) nm) at room temperature and refined to R = 0.153. The unit cell contains 2 zinc ions, 6 insulin molecules and about 3 x 283 water molecules. The atoms in the protein molecules appear well defined, 7 of the 102 side chains in the asymmetric unit have been assigned alternative disordered positions. The electron density over the water molecules has been interpreted in terms of 349 sites, 217 weighted 1.0, 126 weighted 0.5, 5 at 0.33 and 1 at 0.25 giving ca. 282 molecules. The positions and contacts of all the residues belonging to the two A and B chains of the asymmetric unit are shown first and then details of their arrangement in the two insulin molecules, 1 and 2, which are different. The formation from these molecules of a compact dimer and the further aggregation of three dimers to form a hexamer around two zinc ions, follows. It appears that in the packing of the hexamers in the crystal there are conflicting influences; too-close contacts between histidine B5 residues in neighbouring hexamers are probably responsible for movements of atoms at the beginning of the A chain of one of the two molecules of the dimer that initiate movements in other parts, particularly near the end of the B chain. At every stage of the building of the protein structure, residues to chains of definite conformation, molecules, dimers, hexamers and crystals, we can trace the effect of the packing of like groups to like, aliphatic groups together, aromatic groups together, hydrogen-bonded structures, positive and negative ions. Between the protein molecules, the water is distributed in cavities and channels that are continuous throughout the crystals. More than half the water molecules appear directly hydrogen bonded to protein atoms. These are generally in contact with other water molecules in chains and rings of increasing disorder, corresponding with their movement through the crystals. Within the established crystal structure we survey next the distribution of hydrogen bonds within the protein molecules and between water and protein and water and water; all but eight of the active atoms in the protein form at least one hydrogen bond.(ABSTRACT TRUNCATED AT 400 WORDS)

Published
1988
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19. Preparation and activity of nitrated insulin dimer.

Author

Cutfield SM, Dodson GG, Ronco N, and Cutfield JF

Subjects
Amino Acids analysis, Animals, Biopolymers, Chromatography, Gel, Chromatography, High Pressure Liquid, Crystallization, Insulin physiology, Macromolecular Substances, Nitrates isolation & purification, Nitrates physiology, Structure-Activity Relationship, Swine, Tetranitromethane pharmacology, Tyrosine metabolism, Tyrosine physiology, X-Ray Diffraction methods, Insulin isolation & purification
Abstract

Nitration of insulin using tetranitromethane causes polymerisation involving cross-linked tyrosyl residues. By performing this reaction with insulin crystals, in which it is known that B16 tyrosine of one monomer is closely associated with B26 of the neighbouring monomer within the dimer, it has been possible to isolate a covalent dimer of insulin cross-linked between these two tyrosines. It was, however, first necessary to block the reactive A14 tyrosine. Both rhombohedral (hexameric) and cubic (dimeric) pig insulin crystals were used, the latter proving successful in yielding a pure dimeric product as shown by oxidative sulphitolysis and HPLC. The purified nitrated dimer was biologically active (ca. 10% potency compared to monomeric insulin in a lipogenesis assay) suggesting that the residues responsible for insulin's action are present on the surface of the dimer and not buried in the interface.

Published
1986
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21. The isolation, purification and amino-acid sequence of insulin from the teleost fish Cottus scorpius (daddy sculpin).

Author

Cutfield JF, Cutfield SM, Carne A, Emdin SO, and Falkmer S

Subjects
Amino Acid Sequence, Animals, Crystallization, Insulin analysis, Pancreatic Polypeptide analysis, Pancreatic Polypeptide isolation & purification, Zinc analysis, Fishes metabolism, Insulin isolation & purification
Abstract

Insulin from the principal islets of the teleost fish, Cottus scorpius (daddy sculpin), has been isolated and sequenced. Purification involved acid/alcohol extraction, gel filtration, and reverse-phase high-performance liquid chromatography to yield nearly 1 mg pure insulin/g wet weight islet tissue. Biological potency was estimated as 40% compared to porcine insulin. The sculpin insulin crystallised in the absence of zinc ions although zinc is known to be present in the islets in significant amounts. Two other hormones, glucagon and pancreatic polypeptide, were copurified with the insulin, and an N-terminal sequence for pancreatic polypeptide was determined. The primary structure of sculpin insulin shows a number of sequence changes unique so far amongst teleost fish. These changes occur at A14 (Arg), A15 (Val), and B2 (Asp). The B chain contains 29 amino acids and there is no N-terminal extension as seen with several other fish. Presumably as a result of the amino acid substitutions, sculpin insulin does not readily form crystals containing zinc-insulin hexamers, despite the presence of the coordinating B10 His.

Published
1986
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